High-dose radiotherapy and risk-adapted androgen deprivation in localised prostate cancer (DART 01/05): 10-year results of a phase 3 randomised, controlled trial.

BACKGROUND: The optimal duration of androgen deprivation combined with high-dose radiotherapy in prostate cancer remains controversial. The DART 01/05 trial was designed to determine whether long-term androgen deprivation is superior to short-term androgen deprivation when combined with high-dose radiotherapy. The 5-year results showed that 2 years of adjuvant androgen deprivation combined with high-dose radiotherapy significantly improved biochemical control, metastasis, and overall survival, especially in patients with high-risk disease. In this report, we present the 10-year final results of the trial. METHODS: This open-label, phase 3, randomised, controlled trial was done in ten hospitals in Spain. The eligibility criteria included patients aged 18 years or older with histologically confirmed T1c to T3, N0, and M0 adenocarcinoma of the prostate, according to the 2002 classification of the American Joint Committee on Cancer, with intermediate-risk and high-risk factors, prostate-specific antigen (PSA) less than 100 ng/mL, and a Karnofsky performance score of at least 70%. Patients were randomly assigned (1:1) to receive 4 months of neoadjuvant and concomitant short-term androgen deprivation (STAD) plus high-dose radiotherapy (minimum dose 76 Gy; median dose 78 Gy) or to receive the same treatment followed by 24 months of adjuvant long-term androgen deprivation (LTAD), via a randomisation scheduled generated by Statistical Analysis Software programme (version 9.1) and an interactive web response system. Patients assigned to the STAD group received 4 months of neoadjuvant and concomitant androgen deprivation (oral flutamide 750 mg per day or oral bicalutamide 50 mg per day) with subcutaneous goserelin (2 months before and 2 months combined with high-dose radiotherapy). Anti-androgen therapy was added during the first 2 months of treatment. Patients assigned to LTAD continued with goserelin every 3 months for another 24 months. The primary endpoint was biochemical disease-free survival at 5 years. For this 10-year study we analysed overall survival, metastasis-free survival, biochemical disease-free survival, and cause-specific survival. Analysis was by intention to treat. This trial is closed and is registered at ClinicalTrials.gov (NCT02175212) and in the EU Clinical Trials Register (EudraCT 2005-000417-36). FINDINGS: Between Nov 7, 2005, and Dec 20, 2010, 355 patients were enrolled. One patient in the STAD group withdrew from the trial, hence 354 participants were randomly assigned to STAD (n=177) or LTAD (n=177). The median follow-up was 119·4 months (IQR 100·6-124·3). The 10-year biochemical disease-free survival for LTAD was 70·2% (95% CI 63·1-77·3) and for STAD was 62·3% (54·9-69·7; hazard ratio [HR] 0·84; 95% CI 0·50-1·43; p=0·52). At 10 years, overall survival was 78·4% (72·1-84·8) for LTAD and 73·3% (66·6-80·0) for STAD (HR 0·84; 95% CI 0·55-1·27; p=0·40), and metastasis-free survival was 76·0% (69·4-82·7) for LTAD and 70·9% (64·0-77·8) for STAD (HR 0·90; 95% CI, 0·37-2·19; p=0·81). For the subgroup of high-risk patients, the 10-year biochemical disease-free survival was 67·2% (57·2-77·2) for LTAD and 53·7% (43·3-64·1) for STAD (HR 0·90; 95% CI 0·49-1·64; p=0·73), the 10-year overall survival was 78·5% (69·6-87·3) for LTAD and 67·0% (57·3-76·7) for STAD (HR 0·58; 95% CI 0·33-1·01; p=0·054), and the 10-year metastasis-free survival was 76·6% (95% CI 67·6-85·6) for LTAD and 65·0% (55·1-74·8) for STAD (HR 0·89; 95% CI 0·33-2·43; p=0·82). Only 11 (3%) of 354 patients died from prostate cancer, all of them in the high-risk subgroup (five in the LTAD group and six in the STAD group). 76 (21%) patients died from other causes (mainly second malignancies in 31 [9%] and cardiovascular disease in 21 [6%]). No treatment-related deaths were observed. INTERPRETATION: After an extended 10-year follow-up, we were unable to support the significant benefit of LTAD reported at 5 years. However, the magnitude of the benefit was clinically relevant in high-risk patients. Intermediate-risk patients treated with high-dose radiotherapy do not benefit from LTAD. A biological characterisation with the inclusion of genomic testing is needed in the decision-making process. FUNDING: Grupo de Investigación en Oncología Radioterápica and Sociedad Española de Oncología Radioterápica, the National Health Investigation Fund, and AstraZeneca.

High-dose radiotherapy with short-term or long-term androgen deprivation in localised prostate cancer (DART01/05 GICOR): a randomised, controlled, phase 3 trial.

BACKGROUND: The optimum duration of androgen deprivation combined with high-dose radiotherapy in prostate cancer remains undefined. We aimed to determine whether long-term androgen deprivation was superior to short-term androgen deprivation when combined with high-dose radiotherapy. METHODS: In this open-label, multicentre, phase 3 randomised controlled trial, patients were recruited from ten university hospitals throughout Spain. Eligible patients had clinical stage T1c-T3b N0M0 prostate adenocarcinoma with intermediate-risk and high-risk factors according to 2005 National Comprehensive Cancer Network criteria. Patients were randomly assigned (1:1) using a computer-generated randomisation schedule to receive either 4 months of androgen deprivation combined with three-dimensional conformal radiotherapy at a minimum dose of 76 Gy (range 76-82 Gy; short-term androgen deprivation group) or the same treatment followed by 24 months of adjuvant androgen deprivation (long-term androgen deprivation group), stratified by prostate cancer risk group (intermediate risk vs high risk) and participating centre. Patients assigned to the short-term androgen deprivation group received 4 months of neoadjuvant and concomitant androgen deprivation with subcutaneous goserelin (2 months before and 2 months combined with high-dose radiotherapy). Anti-androgen therapy (flutamide 750 mg per day or bicalutamide 50 mg per day) was added during the first 2 months of treatment. Patients assigned to long-term suppression continued with the same luteinising hormone-releasing hormone analogue every 3 months for another 24 months. The primary endpoint was biochemical disease-free survival. Analysis was by intention to treat. This study is registered with ClinicalTrials.gov, number NCT02175212. FINDINGS: Between Nov 7, 2005, and Dec 20, 2010, 178 patients were randomly assigned to receive short-term androgen deprivation and 177 to receive long-term androgen deprivation. After a median follow-up of 63 months (IQR 50-82), 5-year biochemical disease-free survival was significantly better among patients receiving long-term androgen deprivation than among those receiving short-term treatment (90% [95% CI 87-92] vs 81% [78-85]; hazard ratio [HR] 1·88 [95% CI 1·12-3·15]; p=0·01). 5-year overall survival (95% [95% CI 93-97] vs 86% [83-89]; HR 2·48 [95% CI 1·31-4·68]; p=0·009) and 5-year metastasis-free survival (94% [95% CI 92-96] vs 83% [80-86]; HR 2·31 [95% CI 1·23-3·85]; p=0·01) were also significantly better in the long-term androgen deprivation group than in the short-term androgen deprivation group. The effect of long-term androgen deprivation on biochemical disease-free survival, metastasis-free survival, and overall survival was more evident in patients with high-risk disease than in those with low-risk disease. Grade 3 late rectal toxicity was noted in three (2%) of 177 patients in the long-term androgen deprivation group and two (1%) of 178 in the short-term androgen deprivation group; grade 3-4 late urinary toxicity was noted in five (3%) patients in each group. No deaths related to treatment were reported. INTERPRETATION: Compared with short-term androgen deprivation, 2 years of adjuvant androgen deprivation combined with high-dose radiotherapy improved biochemical control and overall survival in patients with prostate cancer, particularly those with high-risk disease, with no increase in late radiation toxicity. Longer follow-up is needed to determine whether men with intermediate-risk disease benefit from more than 4 months of androgen deprivation. FUNDING: Spanish National Health Investigation Fund, AstraZeneca.

HIF1A expression in localized prostate cancer treated with dose escalation radiation therapy.

PURPOSE: To analyze the expression of hypoxia inducible factor 1 alpha (HIF1A) and its correlation with clinical outcome in men with localized prostate cancer (PC) treated with dose escalation radiotherapy (RT) and androgen deprivation (AD). METHODS: Between 1996 and 2004, 129 PC patients who had diagnostic biopsies pre-treatment and 24-36 months following RT were enrolled in this study. Median follow-up was 129 months. Suitable archival diagnostic tissue was obtained from 86 patients. Correlation analysis was done to assess association between HIF1A expression and clinical outcome. RESULTS: HIF1A expression was observed in 25/86 (29%) of diagnostic biopsies, and in 5/14 (36%) of post-RT biopsies. No significant association was noted between HIF1A expression and clinical and treatment parameters. We also failed to show a significant correlation between HIF1A overexpression and outcome. A borderline significant relationship was observed between expression of HIF1A and overall survival (OS) (HR 0.03, p=0.08). CONCLUSION: To our knowledge this is the first study assessing the pattern of change of HIF1A staining in biopsies of patients prior and following treatment. While we did not find significant variations in the expression of HIF1A following radio-hormone therapy, a high HIF1A expression was unexpectedly associated with a borderline improved OS.

Stage I-III Hodgkin's disease: outcome and pattern of failure following treatment with radiation therapy and chemotherapy in a modern era.

PURPOSE: To analyse the long term outcome, pattern of failure and treatment related complications after radiation therapy (RT) with or without chemotherapy for stage I-III Hodgkin's disease (HD). MATERIAL AND METHODS: Detailed records from 86 patients with stage I-III HD treated between 1989 and 1998, were retrospectively reviewed. Seventeen patients with favourable stage I-IIA were treated with RT alone, and the remaining 69 patients with combined modality treatment (CMT). Patients treated with RT received extended-field or subtotal nodal irradiation (STNI) to a total dose of 36-54 Gy, and patients with CMT, received involved-field irradiation to a lower doses, 26-40 Gy. The median follow-up time was 50 months (range 16-180). RESULTS: The 10-year overall survival (OS) for the whole group was 96% (SE 2%), 100% for stage I, 95% for stage II and 100% for stage III patients. Of potential prognostic factors analysed for statistical significance, only the response to chemotherapy (p=0.0393) was found to influence significantly OS rates. Twelve patients (13.9%) relapsed. Salvage treatment was effective in 10 of the 12 relapsed patients. The 10-year freedom from treatment failure (FFTF) was 79% (SE 6%). Although 8 (9.6%) of the 83 surviving patients developed late effects that could represent toxicity from the treatment, no patient died of late complications. CONCLUSIONS: RT alone for favourable early stage HD attains good survival rates with a modest treatment related morbidity. For patients with unfavourable stage II and stage III HD, CMT with limited RT provides a good to excellent prognosis.